A feasible scalable porphyrin dye for dye-sensitized solar cells under one sun and dim light environments

Liu, Yu-Chieh; Chou, Hsien-Hsin; Ho, Feng-Yi; Wei, Hsiang-Jung; Wei, Tzu‐Chien; Yeh, Chen‐Yu

doi:10.1039/c6ta04097g

Cited by 83 publications

(57 citation statements)

References 66 publications

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“…The dark efficiency ( η dark ) is calculated according to η dark = P max / P in , in which P max and P in are maximal power output and intensity for incident light, respectively. In the dark conditions, the photosensitive dyes are irradiated by monochromatic luminescence from LPP phosphors, therefore P in is equal to the photofluorescent light intensity of TiO 2 /LPP photoanode. The maximized dark efficiency was determined to be as high as 26.69 % for devices with green‐emitting LPPs.…”

Section: All‐weather Solar Cells Harvest Energy In the Daytime And Inmentioning

confidence: 94%

All‐Weather Solar Cells: A Rising Photovoltaic Revolution

Tang

2017

Chemistry A European J

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Solar cells have been considered as one of the foremost solutions to energy and environmental problems because of clean, high efficiency, cost-effective, and inexhaustible features. The historical development and state-of-the-art solar cells mainly focus on elevating photoelectric conversion efficiency upon direct sunlight illumination. It is still a challenging problem to realize persistent high-efficiency power generation in rainy, foggy, haze, and dark-light conditions (night). The physical proof-of-concept for all-weather solar cells opens a door for an upcoming photovoltaic revolution. Our group has been exploring constructive routes to build all-weather solar cells so that these advanced photovoltaic technologies can be an indication for global solar industry in bringing down the cost of energy harvesting. How the all-weather solar cells are built without reducing photo performances and why such architectures can realize electricity outputs with no visible-light are discussed. Potential pathways and opportunities to enrich all-weather solar cell families are envisaged. The aspects discussed here may enable researchers to develop undiscovered abilities and to explore wide applications of advanced photovoltaics.

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Section: All‐weather Solar Cells Harvest Energy In the Daytime And Inmentioning

confidence: 94%

All‐Weather Solar Cells: A Rising Photovoltaic Revolution

Tang

2017

Chemistry A European J

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“…For precise photovoltaic measurement, the shielding mask (0.36 cm 2 ) was attached to the illuminating side of the device. The electrolyte included 0.5 M 4‐tertbutyl pyridine, 0.1 M guanidinium thiocyanate, 0.05 M LiI, 0.03 M I 2 , and 1.0 M 1,3‐dimethylimidazole iodide in acetonitrile/valeronitrile (85:15, vol/vol) …”

Section: Methodsmentioning

confidence: 99%

Effect of long alkyl chains of aniline donor on the photovoltaic performance of D‐π‐A zinc porphyrin for dye‐sensitized solar cells

Chen

Liu

Yeh

2019

J Chinese Chemical Soc

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Three novel dyes of JJ1, JJ2, and JJ6 featured zinc porphyrin as a basic core structure; N, N‐alkyl‐4‐(prop‐1‐yn‐1‐yl)aniline as an electron donor linked to meso‐10‐position; 4‐(prop‐1‐yn‐1‐yl)benzoic acid as an electron acceptor linked to meso‐20‐position; and 2,6‐bis(dodecyloxy)phenyl or 2,6‐bis(octyloxy)phenyl respectively linked to meso‐5 and meso‐15‐positions of zinc porphyrin have been synthesized and used for dye‐sensitized solar cells. Porphyrin JJ6 featured the shortest alkyl group (─C4H9) on the donor, whereas JJ2 contained the longest alkyl groups (─C12H25), and JJ1 has a medium length of octyl groups. With these new porphyrin sensitizers, we observed that JJ6 has 7.55% power conversion efficiency under simulated one‐sun illumination (AM 1.5 G, 100 mW/cm2) with JSC = 18.64 mA/cm2, VOC = 0.66 V, and fill factor (FF) = 0.61, which was higher than the other two; JJ1 (7.35%) with JSC = 18.83 mA/cm2, VOC = 0.68 V, and FF = 0.60; and JJ2 (6.33%) with JSC = 15.69 mA/cm2, VOC = 0.62 V, and FF = 0.65. The power conversion efficiency of JJ6 and JJ1 were higher than JJ2, demonstrating that the lengthy alkyl groups on the aniline cause a decrease in efficiency of the devices.

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“…Another report from Yeha nd co-workers investigated the influences of Li + and GuSCN ( Figure 1) additives together with CDCA as the co-adsorbent with ap orphyrin-based dye( referred to as Y1A1, Figure 4) for high-performance dye-sensi-tized solar cells. [26] The GuSCN-free electrolyte improves the PCE by reducing charger ecombination and electron lifetime upon addition of Li + additive. PCE values werem easured up to 9.22 %( V OC = 0.658 V, J SC = 18.57 mA cm À2 ,a nd FF = 0.753) using I À /I 3 À rather than Co 2 + /3 + electrolytes in the presence of 0.3 mm CDCA as the co-adsorbent when measured at 1sun illumination.…”

Section: Co-adsorbentsmentioning

confidence: 99%

Role of Co‐Sensitizers in Dye‐Sensitized Solar Cells

Krishna

Mrinalini

et al. 2017

ChemSusChem

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Co-sensitization is a popular route towards improved efficiency and stability of dye-sensitized solar cells (DSSCs). In this context, the power conversion efficiency (PCE) values of DSSCs incorporating Ru- and porphyrin-based dyes can be improved from 8-11 % to 11-14 % after the addition of additives, co-adsorbents, and co-sensitizers that reduce aggregation and charge recombination in the device. Among the three supporting material types, co-sensitizers play a major role to enhance the performance and stability of DSSCs, which is requried for commercialization. In this Minireview, we highlight the role co-sensitizers play in improving photovoltaic performance of devices containing Ru- and porphyrin-based sensitizers.

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A feasible scalable porphyrin dye for dye-sensitized solar cells under one sun and dim light environments

Cited by 83 publications

References 66 publications

All‐Weather Solar Cells: A Rising Photovoltaic Revolution

All‐Weather Solar Cells: A Rising Photovoltaic Revolution

Effect of long alkyl chains of aniline donor on the photovoltaic performance of D‐π‐A zinc porphyrin for dye‐sensitized solar cells

Role of Co‐Sensitizers in Dye‐Sensitized Solar Cells

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